Your search keyword '"Manatt KS"' showing total 6 results

1. Investigating Habitability with an Integrated Rock-Climbing Robot and Astrobiology Instrument Suite.

Author

Uckert K, Parness A, Chanover N, Eshelman EJ, Abcouwer N, Nash J, Detry R, Fuller C, Voelz D, Hull R, Flannery D, Bhartia R, Manatt KS, Abbey WJ, and Boston P

Subjects

Caves, Extraterrestrial Environment, Minerals, Exobiology instrumentation, Mars, Robotics

Abstract

A prototype rover carrying an astrobiology payload was developed and deployed at analog field sites to mature generalized system architectures capable of searching for biosignatures in extreme terrain across the Solar System. Specifically, the four-legged Limbed Excursion Mechanical Utility Robot (LEMUR) 3 climbing robot with microspine grippers carried three instruments: a micro-X-ray fluorescence instrument based on the Mars 2020 mission's Planetary Instrument for X-ray Lithochemistry provided elemental chemistry; a deep-ultraviolet fluorescence instrument based on Mars 2020's Scanning Habitable Environments with Raman and Luminescence for Organics and Chemicals mapped organics in bacterial communities on opaque substrates; and a near-infrared acousto-optic tunable filter-based point spectrometer identified minerals and organics in the 1.6-3.6 μm range. The rover also carried a light detection and ranging and a color camera for both science and navigation. Combined, this payload detects astrobiologically important classes of rock components (elements, minerals, and organics) in extreme terrain, which, as demonstrated in this work, can reveal a correlation between textural biosignatures and the organics or elements expected to preserve them in a habitable environment. Across >10 field tests, milestones were achieved in instrument operations, autonomous mobility in extreme terrain, and system integration that can inform future planetary science mission architectures. Contributions include (1) system-level demonstration of mock missions to the vertical exposures of Mars lava tube caves and Mars canyon walls, (2) demonstration of multi-instrument integration into a confocal arrangement with surface scanning capabilities, and (3) demonstration of automated focus stacking algorithms for improved signal-to-noise ratios and reduced operation time.

Published

2020

2. Subsurface In Situ Detection of Microbes and Diverse Organic Matter Hotspots in the Greenland Ice Sheet.

Author

Malaska MJ, Bhartia R, Manatt KS, Priscu JC, Abbey WJ, Mellerowicz B, Palmowski J, Paulsen GL, Zacny K, Eshelman EJ, and D'Andrilli J

Subjects

Greenland, Ice Cover chemistry, Ice Cover microbiology, Solar System

Abstract

We used a deep-ultraviolet fluorescence mapping spectrometer, coupled to a drill system, to scan from the surface to 105 m depth into the Greenland ice sheet. The scan included firn and glacial ice and demonstrated that the instrument is able to determine small (mm) and large (cm) scale regions of organic matter concentration and discriminate spectral types of organic matter at high resolution. Both a linear point cloud scanning mode and a raster mapping mode were used to detect and localize microbial and organic matter "hotspots" embedded in the ice. Our instrument revealed diverse spectral signatures. Most hotspots were <20 mm in diameter, clearly isolated from other hotspots, and distributed stochastically; there was no evidence of layering in the ice at the fine scales examined (100 μm per pixel). The spectral signatures were consistent with organic matter fluorescence from microbes, lignins, fused-ring aromatic molecules, including polycyclic aromatic hydrocarbons, and biologically derived materials such as fulvic acids. In situ detection of organic matter hotspots in ice prevents loss of spatial information and signal dilution when compared with traditional bulk analysis of ice core meltwaters. Our methodology could be useful for detecting microbial and organic hotspots in terrestrial icy environments and on future missions to the Ocean Worlds of our Solar System.

Published

2020

3. WATSON: In Situ Organic Detection in Subsurface Ice Using Deep-UV Fluorescence Spectroscopy.

Author

Eshelman EJ, Malaska MJ, Manatt KS, Doloboff IJ, Wanger G, Willis MC, Abbey WJ, Beegle LW, Priscu JC, and Bhartia R

Subjects

Jupiter, Mars, Spectrometry, Fluorescence methods, Ultraviolet Rays, Exobiology methods, Extraterrestrial Environment chemistry, Ice Cover chemistry, Organic Chemicals analysis

Abstract

Terrestrial icy environments have been found to preserve organic material and contain habitable niches for microbial life. The cryosphere of other planetary bodies may therefore also serve as an accessible location to search for signs of life. The Wireline Analysis Tool for the Subsurface Observation of Northern ice sheets (WATSON) is a compact deep-UV fluorescence spectrometer for nondestructive ice borehole analysis and spatial mapping of organics and microbes, intended to address the heterogeneity and low bulk densities of organics and microbial cells in ice. WATSON can be either operated standalone or integrated into a wireline drilling system. We present an overview of the WATSON instrument and results from laboratory experiments intended to determine (i) the sensitivity of WATSON to organic material in a water ice matrix and (ii) the ability to detect organic material under various thicknesses of ice. The results of these experiments show that in bubbled ice the instrument has a depth of penetration of 10 mm and a detection limit of fewer than 300 cells. WATSON incorporates a scanning system that can map the distribution of organics and microbes over a 75 by 25 mm area. WATSON demonstrates a sensitive fluorescence mapping technique for organic and microbial detection in icy environments including terrestrial glaciers and ice sheets, and planetary surfaces including Europa, Enceladus, or the martian polar caps.

Published

2019

4. Field demonstration of an instrument performing automatic classification of geologic surfaces.

Author

Bekker DL, Thompson DR, Abbey WJ, Cabrol NA, Francis R, Manatt KS, Ortega KF, and Wagstaff KL

Subjects

Algorithms, Automation, California, Image Processing, Computer-Assisted, Photography instrumentation, ROC Curve, Surface Properties, User-Computer Interface, Geology instrumentation

Abstract

This work presents a method with which to automate simple aspects of geologic image analysis during space exploration. Automated image analysis on board the spacecraft can make operations more efficient by generating compressed maps of long traverses for summary downlink. It can also enable immediate automatic responses to science targets of opportunity, improving the quality of targeted measurements collected with each command cycle. In addition, automated analyses on Earth can process large image catalogs, such as the growing database of Mars surface images, permitting more timely and quantitative summaries that inform tactical mission operations. We present TextureCam, a new instrument that incorporates real-time image analysis to produce texture-sensitive classifications of geologic surfaces in mesoscale scenes. A series of tests at the Cima Volcanic Field in the Mojave Desert, California, demonstrated mesoscale surficial mapping at two distinct sites of geologic interest.

Published

2014

5. Monitoring space shuttle air quality using the Jet Propulsion Laboratory electronic nose.

Author

Ryan MA, Zhou H, Buehler MG, Manatt KS, Mowrey VS, Jackson SP, Kisor AK, Shevade AV, and Homer ML

Subjects

Air Conditioning, Biosensing Techniques, Carbon analysis, Environmental Monitoring methods, Membranes, Artificial, Noise, Polymers, Reproducibility of Results, Sensitivity and Specificity, Air Pollution, Indoor analysis, Environmental Monitoring instrumentation, Gases analysis, Humidity, Life Support Systems instrumentation, Space Flight instrumentation, Spacecraft instrumentation, Weightlessness

Abstract

A miniature electronic nose (ENose) has been designed and built at the Jet Propulsion Laboratory (JPL), Pasadena, CA, and was designed to detect, identify, and quantify ten common contaminants and relative humidity changes. The sensing array includes 32 sensing films made from polymer carbon-black composites. Event identification and quantification were done using the Levenberg-Marquart nonlinear least squares method. After successful ground training, this ENose was used in a demonstration experiment aboard STS-95 (October-November, 1998), in which the ENose was operated continuously for six days and recorded the sensors' response to the air in the mid-deck. Air samples were collected daily and analyzed independently after the flight. Changes in shuttle-cabin humidity were detected and quantified by the JPL ENose; neither the ENose nor the air samples detected any of the contaminants on the target list. The device is microgravity insensitive.

Published

2004

6. Molecular modeling of polymer composite-analyte interactions in electronic nose sensors.

Author

Shevade AV, Ryan MA, Homer ML, Manfreda AM, Zhou H, and Manatt KS

Subjects

Air Conditioning, Biosensing Techniques, Carbon analysis, Ecological Systems, Closed, Electronics, Environmental Monitoring instrumentation, Models, Chemical, Molecular Structure, Naphthalenes chemistry, Polymers analysis, Solvents, Structure-Activity Relationship, Air Pollution, Indoor analysis, Carbon chemistry, Environmental Monitoring methods, Models, Molecular, Polymers chemistry

Abstract

We report a molecular modeling study to investigate the polymer-carbon black (CB) composite-analyte interactions in resistive sensors. These sensors comprise the JPL electronic nose (ENose) sensing array developed for monitoring breathing air in human habitats. The polymer in the composite is modeled based on its stereoisomerism and sequence isomerism, while the CB is modeled as uncharged naphthalene rings with no hydrogens. The Dreiding 2.21 force field is used for the polymer, solvent molecules and graphite parameters are assigned to the carbon black atoms. A combination of molecular mechanics (MM) and molecular dynamics (NPT-MD and NVT-MD) techniques are used to obtain the equilibrium composite structure by inserting naphthalene rings in the polymer matrix. Polymers considered for this work include poly(4-vinylphenol), polyethylene oxide, and ethyl cellulose. Analytes studied are representative of both inorganic and organic compounds. The results are analyzed for the composite microstructure by calculating the radial distribution profiles as well as for the sensor response by predicting the interaction energies of the analytes with the composites., (c2003 Elsevier Science B.V. All rights reserved.)

Published

2003